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Course
Code: : 5103222 Course
Name : Advanced Fluid Mechanics III Instructor
:Asst. Assoc. Dr. Refet
Karadağ Theoretical / Practical / Credit : 3 / 0 / 3
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HARRAN UNİVERSITY ENGINEERING FACULTY
MECHANICAL ENGI0NEERING DEPARTMENT
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Course Name |
Code |
Semester |
T+U |
Credit |
AKTS |
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Advanced Fluid Mechanics III |
5103222 |
Spring |
3+0 |
3 |
5 |
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Prerequisite Courses |
None |
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Language of Course |
Turkish |
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Course class |
Elective |
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Coordinator of Course |
Asst. Assoc. Dr. Refet Karadağ |
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Instructor |
Asst. Assoc. Dr. Refet Karadağ |
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Course Assistant |
- |
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Objective of course |
Teaching
methods used in numerical solution of flow problems and gain skills to apply
the solution of problems. |
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Course Learning Output |
Students
taking this course, all kinds of numerical solution of flow problems the
algorithms necessary for the development of computer programs will be
learned. |
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Course Contents |
Classification
of fluids. Basic Equations. Problem solving technique. Numerical methods of
characteristics, advantages and disadvantages. Basic steps for numerical
solution methods. Decomposition methods the properties. Solution of systems
of linear algebraic equations. Control volume method for the solution of
problems of diffusion the convection. Control volume method for the solution
of the Navier-Stokes equations. SIMPLE, SIMPLER,
the Piso SIMPLEC algorithms. Vorticity
stream function solution of the Navier-Stokes
equations. Finite difference solution of boundary layer equations.
Computational fluid dynamics (CFD) analysis. |
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Weeks |
Plan
of Course at Semester |
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1 |
Definitions, classification of fluids, Basic Laws, Mathematical modeling. |
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2 |
Problem solving technique. Engineering software |
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3 |
Conservation of mass, momentum equation (Newton's Second Law), Conservation of Energy. |
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4 |
Dimensional analysis and modeling. Experimental tests and incomplete similarity. The correlation between the experimental systems and experimental data. |
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5 |
Decomposition (Diskritizasyon) Methods: Finite Difference, Control Volume, Finite Solution of Equation Elemanlar.Cebirsel: Direct Methods, Gaussian Elimination Method, Gauss Jordan Elimination Method (TDMA), İteraktif Methods. |
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6 |
Two-and Three-Dimensional Heat Equation solution, and Underrelaxation Overrelaxation. |
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7 |
Convection and Diffusion Equations. One-dimensional equations. General formulation, Full Solution, exponential formulation. Comparison of different formulations. |
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8 |
MID-TERM EXAM |
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9 |
Convection and Diffusion Equations: Two-and Three-Dimensional Equations. |
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10 |
Two-and Three-Dimensional Solution of the Navier-Stokes Equations: Variables (Primitive Variable) method, the SIMPLE and SIMPLER algorithm. |
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11 |
Stream function, vorticity method. |
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12 |
Computational fluid dynamics (CFD), network creation, boundary conditions, conditions of work. |
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13 |
CFD analysis of laminar and turbulent, compressible flow CFD analysis. CFD analysis of open channel flow. |
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14 |
FINAL EXAM |
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General Sufficiency |
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İn all kinds of flow problems using analytical and numerical methods and developing the algorithms necessary
for computer programs. |
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References |
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1. Akışkanlar mekaniği
temelleri ve uygulamaları- Yunus A. ÇENGEL ve John M. CIMBALA- Türkçesi Tahsin Engin,
Halil Rıdvan Öz, Hasan Küçük, Şevki Çeşmeci- Güven Bilimsel, 2006 2. [Akışkanlar
Mekaniği – Frank M. White – Türkçesi
: Kadir Kırkköprü, Erkan Ayder Literatür Yayınevi –
2004 3. Akışkanlar
Mekaniği – Habip Umur – Uludağ Üniv. Yayınları –
2001 4. Akışkanlar
Mekaniği – Muhittin Soğukoğlu, Birsen Yayın Dağıtım
– 1995 5. Akışkanlar
Mekaniği – Haluk Örs – Boğaziçi Üniv., 1994 6. Introduction to Fluid Mechanics – Robert W. Fox , Alen T. Mc Donald,
4th Edition – John Wiley-Sons - 2001 7. Akışkanlar
Mekaniği Problemleri, Hasmet Türkoğlu ve Nuri
Yücel, Gazi Üniv. – 2002 |
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Form of Assessment |
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Mid Exam and Task/Project Average of
Arithmetical: %40 Final:%60 Projects:- Homeworks:- |